Gradisca d'Isonzo, Italy
9-10 December 2019
Book of abstracts
MASB OPHYSICS
ORKSHOP
Contents
Contents iii
Welcome 1
List of participants 3
Program 5
Abstracts 9
Corominas-Murtra, Bernat – Criticality and phase transitions at the onset of morpho-
genesis . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Rozman, Jan – 3D vertex model of ventral furrow formation in fruit fly . . . . . . . . 11
Svetina, Saša – The effect of a single Piezo1 trimer on shapes of phospholipid vesicles . 12
Slejko, Ema – The influence of the poly(ethylene glycol) on the mean activity coeffcients
of NaCl aqueous solutions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Vuletic, Tomislav – FCS study of interaction of DNA and supramolecular systems with
adamantyl guanidines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
Staniscia, Fabio – Passive viscoelastic response of striated muscles . . . . . . . . . . . 15
Doncevic, Lucija – Protein self-association . . . . . . . . . . . . . . . . . . . . . . . . 16
V. Guzman, Horacio – Quantifying the disassembly of viral capsids from a multiscale
molecular simulation approach . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
Zankoc, Clément – Nonlinear stochastic dynamics of adherens junctions . . . . . . . 18
Papež, Petra – Hydration of lower alcohols using theoretical methods . . . . . . . . . 19
Šiber, Antonio – Collapsing pollen grains . . . . . . . . . . . . . . . . . . . . . . . . 21
Rosa, Angelo – Untangled ring polymers in melts: The Physics of crumpling . . . . . . 22
Franzini, Stefano – hicRED: A spectral method for comparing HiC-maps . . . . . . . . 23
Božic, Anže – Coupling electrostatics and elasticity of virus capsids . . . . . . . . . . 24
Bernetti, Mattia – Combining molecular dynamics simulations with SAXS experiments
to characterize RNA conformational dynamics . . . . . . . . . . . . . . . . . . . 25
iii
Calonaci, Nicola – Machine-learning experimental data for RNA structure prediction . 26
Erceg, Ina – The kinetics of bovine serum albumine adsorption on calcium ohosphate
and TiO2 nanoparticles or nanotubes nanocomposites . . . . . . . . . . . . . . . 27
Sadžak, Anja – Protection of lipid membranes during oxidative stress using flavonoid
embedded silica nanoparticles . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
Štimac, Adela – Measurement of the biomolecular interaction between plant lectin and
peptidoglycan functionalized self-assembled hybrid bilayers by a quartz crystal
microbalance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
Kanduc, Matej – Biological liquids under tension . . . . . . . . . . . . . . . . . . . . 31
Gnidovec, Andraz – Orientational ordering of point dipoles on a sphere . . . . . . . . 32
Krajnc, Matej – Active elastic networks as models of biological tissues . . . . . . . . . 33
Ziherl, Primoz – Morphologies of vesicle doublets: Competition among surface tension,
bending elasticity, and adhesion . . . . . . . . . . . . . . . . . . . . . . . . . . 34
Index of authors 35
Welcome
Dear participant,
It is our pleasure to welcome you in Gradisca d’Isonzo for the traditional cross-border
Christmas Biophysics Workshops (XBW).
This series of workshops, which covers both biophysics and soft-matter physics, was
started by Rudi Podgornik and Silvia Tomic in 2006 in Zagreb and was so successful that
it was pass down from year to year and country to country without interruptions to this day.
As previous participants know by experience, the key to the success of the initiative is the
informal and relaxed atmosphere where researchers, especially young ones, can discuss their
recent or ongoing work in a friendly setting that is ideally poised to establish collaborations.
We hope you will enjoy the activity, the social evening and the stay in Gradisca.
Irene Adroher-Benítez and Cristian Micheletti
1
List of participants
Austria
. Corominas-Murtra, Bernat. Institute of Science and Technology Austria (Klosterneuburg).
Croatia
. Cindric, Mario. Ruder Boškovic Institut (Zagreb).
. Doncevic, Lucija. University of Zagreb (Zagreb).
. Erceg, Ina. Ruder Boškovic Institute (Zagreb).
. Sadžak, Anja. Ruder Boškovic Institute (Zagreb).
. Šiber, Antonio. Institute of Physics (Zagreb).
. Štimac, Adela. University of Zagreb (Zagreb).
. Svetlicic, Ema. University of Zagreb (Zagreb).
. Vuletic, Tomislav. Institute of Physics (Zagreb).
Italy
. Adroher-Benítez, Irene. Scuola Internazionale Superiore di Studi Avanzati (Trieste).
. Bernetti, Mattia. Scuola Internazionale Superiore di Studi Avanzati (Trieste).
. Calonaci, Nicola. Scuola Internazionale Superiore di Studi Avanzati (Trieste).
. Franzini, Stefano. Scuola Internazionale Superiore di Studi Avanzati (Trieste).
. Micheletti, Cristian. Scuola Internazionale Superiore di Studi Avanzati (Trieste).
. Rosa, Angelo. Scuola Internazionale Superiore di Studi Avanzati (Trieste).
Slovenia
. Božic, Anže. Jožef Stefan Institute (Ljubljana).
. Gnidovec, Andraž. University of Ljubljana (Ljubljana).
3
List of participants
. Kanduc, Matej. Jožef Stefan Institute (Ljubljana).
. Krajnc, Matej. Jožef Stefan Institute (Ljubljana).
. Papež, Petra. National Institute of Chemistry (Ljubljana).
. Popadic, Aleksandar. National Institute of Chemistry (Ljubljana).
. Rozman, Jan. Jožef Stefan Institute (Ljubljana).
. Slejko, Ema. National Institute of Chemistry (Ljubljana).
. Staniscia, Fabio. Jožef Stefan Institute (Ljubljana).
. Svetina, Saša. University of Ljubljana/Jožef Stefan Institute (Ljubljana).
. V. Guzmán, Horacio. Jožef Stefan Institute (Ljubljana).
. Zankoc, Clément. Jožef Stefan Institute (Ljubljana).
. Ziherl, Primoz. University of Ljubljana/Jožef Stefan Institute (Ljubljana).
4
Program
Monday 09/12/19
09:50 - 10:00 Welcome by Cristian Micheletti
10:00 - 11:15 Session 1: Cellular Systems – Chair: Irene Adroher-Benítez
10:00 - 10:25 Bernat Corominas-Murtra
Criticality and phase transitions at the onset of morphogenesis.
10:25 - 10:50 Jan Rozman
3D Vertex Model of Ventral Furrow Formation in Fruit Fly.
10:50 - 11:15 Saša Svetina
The effect of a single Piezo1 trimer on shapes of phospholipid
vesicles.
11:15 - 11:45 Coffee break
11:45 - 13:25 Session 2: Biophysics – Chair: Antonio Šiber
11:45 - 12:10 Ema Slejko
The influence of the poly(ethylene glycol) on the mean activity
coefficients of NaCl aqueous solutions.
12:10 - 12:35 Tomislav Vuletic
FCS study of interaction of DNA and supramolecular systems
with adamantyl guanidines.
12:35 - 13:00 Fabio Staniscia
Passive viscoelastic response of striated muscles.
13:00 - 13:25 Lucija Doncevic
Protein self-association.
13:30 - 14:30 Lunch
14:30 - 15:00 Check in
5
Program
15:00 - 16:40 Session 3: Soft Matter – Chair: Primoz Ziherl
15:00 - 15:25 Horacio V. Guzmán
Quantifying the disassembly of viral capsids from a multiscale
molecular simulation approach.
15:25 - 15:50 Clément Zankoc
Nonlinear stochastic dynamics of adherens junctions.
15:50 - 16:15 Petra Papež
Hydration of lower alcohols using theoretical methods.
16:15 - 16:40 Antonio Šiber
Collapsing pollen grains.
16:40 - 17:10 Coffee break
17:10 - 19:15 Session 4: Biomolecules, structure and function – Chair: Matej Kanduc
17:10 - 17:35 Angelo Rosa
Untangled ring polymers in melts: The Physics of crumpling.
17:35 - 18:00 Stefano Franzini
hicRED: A spectral method for comparing HiC-maps.
18:00 - 18:25 Anze Bozic
Coupling electrostatics and elasticity of virus capsids.
18:25 - 18:50 Mattia Bernetti
Combining molecular dynamics simulations with SAXS experi-
ments to characterize RNA conformational dynamics.
18:50 - 19:15 Nicola Calonaci
Machine-learning experimental data for RNA structure predic-
tion.
20:15 - 22:00 Social dinner
22:00 - ? Grappa discussion
6
Program
Tuesday 10/12/19
07:00 - 09:15 Breakfast
09:15 - 10:30 Session 5: Biophysics – Chair: Tomislav Vuletic
09:15 - 09:40 Ina Erceg
The kinetics of bovine serum albumine adsorption on calcium
ohosphate and TiO2 nanoparticles or nanotubes nanocompos-
ites.
09:40 - 10:05 Anja Sadžak
Protection of lipid membranes during oxidative stress using flavonoid
embedded silica nanoparticles.
10:05 - 10:30 Adela Štimac
Measurement of the biomolecular interaction between plant lectin
and peptidoglycan functionalized self-assembled hybrid bilayers
by a quartz crystal microbalance.
10:30 - 11:20 Coffee break and check out
11:20 - 13:00 Session 6: Soft Matter – Chair: Adela Štimac
11:20 - 11:45 Matej Kanduc
Biological liquids under tension.
11:45 - 12:10 Andraž Gnidovec
Orientational ordering of point dipoles on a sphere.
12:10 - 12:35 Matej Krajnc
Active elastic networks as models of biological tissues.
12:35 - 13:00 Primoz Ziherl
Morphologies of vesicle doublets: Competition among surface
tension, bending elasticity, and adhesion.
13:00 - 14:00 Lunch
14:00 Departure
7
Abstracts
9
Bernat Corominas-Murtra
Criticality and phase transitions at the onset of morphogenesis
Bernat Corominas-Murtra?
?Institute of Science and Technology Austria, Klosterneuburg, Austria.
Tissue morphogenesis in multicellular organisms is one of the most fascinating phenom-
ena of nature. From a small collection of apparently identical cells, an explosion of complexity
leads to the formation of a new, fully developed organism. Despite the enormous number of
variables the process relies upon, morphogenesis is a very robust process that occurs follow-
ing a well ordered sequence of stages through apparently fragile metastable states. A crucial
question is: what are the driving forces that enable and promote the transition from one state
to the next? Recent findings reported abrupt changes in the material properties of the tissues,
pointing to the hypothesis that such transitions can be actually conceptualized as structural
phase transitions. However, no approach has been able to connect the assumptions of a
microscopic theory –in the sense of statistical mechanics– to the observed, macroscopic ob-
servables. In this talk I will show how, in the first stages of the development of the zebrafish
embryo, the network structure of the tissue suffers dramatic changes that are surprisingly
well characterized as rigid-to-fluid phase transitions, a phenomenon intimately linked to per-
colation and that would act as a critical regulator of embryo morphogenesis. Interesting
deviations are observed in the systems genetically modified where cell cycle gets desynchro-
nized and, in consequence so does the ability of uniform loss/gain of cell contacts that leads
to the phase transition. Crucially, those embryos show a non-uniform fluidization/transition
and fail to undergo normal tissue morphogenesis. This negative observation acts as a coun-
terfactual proof of our results, supporting the hypothesis that the observed transition plays
a critical role in embryo development. Our results are able to bridge, for the first time, the
theoretical approach based on the patterns of cell interactions with macroscopic observables
and match them with real data coming from experiments. This opens a vast and intriguing
scenario towards the theoretical understanding of this crucial biological phenomenon where
criticality theory is called to occupy a prominent role.
10
Jan Rozman
3D vertex model of ventral furrow formation in fruit fly
Jan Rozman?
?Department of Theoretical Physics, Jožef Stefan Institute, Ljubljana, Slovenia.
The formation of the ventral furrow - an invagination of the ventral side of the early
embryo - is a key morphogenic event during the gastrulation of the fruit fly Drosophila
Melanogaster, and one of the most studied morphogenetic processes from both biological
and biophysical perspective. Previous studies have shown that a 2D surface tension based
vertex model can reproduce the invaginated morphology, either as a consequence of collec-
tive mechanics of identical cells1 or in a system with multiple mechanically distinct groups
of cells2. We build on these results by devising a 3D vertex model of the invaginated tissue,
reproducing the formation of the ventral furrow in a simplified, cylindrical geometry. We
generalize the model by adding time-dependent tensions along the apical and basal edges of
individual cells, analyzing the mechanical effects of the resulting T1 transitions on the shape
of the tissue.
References
[1] A. Hocevar Brezavšcek, M. Rauzi, M. Leptin, and P. Ziherl, A model of epithelial invagination
driven by collective mechanics of identical cells, Biophys. J. 103 5, 1069 (2012).
[2] M. Rauzi, U. Krzic, T. E. Saunders, M. Krajnc, P. Ziherl, L. Hufnagel, and M. Leptin, Embryo-scale
tissue mechanics during Drosophila gastrulation movements, Nat. Commun. 6, 8677 (2015).
11
Saša Svetina
The effect of a single Piezo1 trimer on shapes of phospholipid vesi-
cles
Saša Svetina?†
?Institute of Biophysics, Faculty of Medicine, University of Ljubljana, Slovenia.†Department of Theoretical Physics, Jožef Stefan Institute, Ljubljana, Slovenia.
Piezo1 trimer is a large (∼ 0.9 MDa) mechanosensitive protein that converts mechanical
forces on cellular membranes into electrochemical signals in physiological processes such as
blood vessel formation and vascular structure, hearing, touch, notiception etc. It also plays a
role in the regulation of red blood cell volume. The mechanism of Piezo1 mechanosensitivity
is still a matter of research. Several recent cryo-electron microscope studies have revealed
its dome-like structure characterized by three “propeller-like” extensions. It was also demon-
strated that Piezo1 affects shapes of phospholipid vesicles. Here we shall present the results
of a corresponding theoretical model. The shape of a vesicle with a single Piezo1 trimer em-
bedded onto its membrane is predicted by minimizing the sum of membrane bending energy
and the elastic energy of the protein. It is shown how the radius of curvature on Piezo1 side
of vesicle depends on the radius of curvature on opposite vesicle pole.
12
Ema Slejko
The influence of the poly(ethylene glycol) on the mean activity
coeffcients of NaCl aqueous solutions
Ema Slejko?, Barbara Hribar-Lee?
?National Institute of Chemistry, Ljubljana, Slovenia.
The influence of the poly(ethylene glycol) on the mean activity coefficients of NaCl aque-
ous solutions
In this work I have systematically researched the influence of different poly(ethylene
glycol) (PEG) on mean activity coefficient of sodium chloride in water solutions.
By measuring the voltage of galvanic cell (as indicator electrode ISE of chloride and
sodium were used) the mean activity coefficient of NaCl was determined as a function of salt
concentration. From measurements it can be seen, that activity coefficient of NaCl decreases
with concentration of salt, however at high concentrations it starts to increase. Also, the
increase of activity coefficient when PEG is added is observed.
In second part of this work mean activity coefficient of NaCl in PEG aqueous solutions
were calculated with theoretical methods. For calculations of mean activity coefficient of
NaCl in PEG, Ornstein-Zernike integral equation with HNC approximation was used. Further
relative permittivity at different conditions was calculated. It can be seen that relative per-
mittivity of water solutions of salts is lower than of pure water. It can also be observed that
by adding PEG in to solution relative permittivity is additionally lower.
13
Tomislav Vuletic
FCS study of interaction of DNA and supramolecular systems with
adamantyl guanidines
Tomislav Vuletic?, Adela Štimac†, Leo Frkanec‡, Ruža Frkanec†
?Institute of Physics, Zagreb, Croatia.†Centre for Research and Knowledge Transfer in Biotechology, University of Zagreb, Croatia.‡Ruder Boškovic Institute, Zagreb, Croatia.
Fluorescence correlation spectroscopy (FCS) was applied to examine the interactions be-
tween ternary systems of fluorescently labeled DNA120* and nanoparticles functionalized
with guanidinium group on the surface. The guanidinium group appeared particularly well
suited for interaction with the phosphate residues of polynucleotides through establishing a
characteristic pair of hydrogen bonds. FCS is a non-destructive and powerful technique that
is based on fluctuations of fluorescence intensity over time within a small observation volume
under equilibrium conditions.
In this work, FCS is used to detect the formation of complex between small and quickly
diffusing fluorescently labeled DNA120* (Cy5-labeled double-stranded 120 base-pair DNA)
and larger, slowly diffusing nanoparticles. We performed a series of FCS measurements of
diffusion times for DNA120* in HEPES buffer in presence of a range of concentrations of vari-
ous nanovesicles. FCS result for DNA120* only, without nanoparticles, serves as the baseline.
In Supplementary material we present the prerequisite steps to take to ascertain that the FCS
experiment measures the relevant features of the system under study.
14
Fabio Staniscia
Passive viscoelastic response of striated muscles
Fabio Staniscia?
?Department of Theoretical Physics, Jožef Stefan Institute, Ljubljana, Slovenia.
Muscle cells with sarcomeric structure exhibit highly nontrivial passive mechanical re-
sponse. The difficulty of its continuum modeling is due to the presence of long-range inter-
actions transmitted by extended protein skeleton. To build a rheological model for muscle
’material’ we use a stochastic micromodel and derive a linear response theory for a half-
sarcomere. Instead of the first order rheological equation, anticipated by A.V. Hill on the
phenomenological grounds, we obtain a novel second order equation. We use the values of
the microscopic parameters for frog muscles to show that the proposed rheological model is
in excellent quantitative agreement with physiological experiments.
15
Lucija Doncevic
Protein self-association
Lucija Doncevic?, A. L. Brkic†, Mario Cindric‡
?Faculty of Sciences, Department of Chemistry, University of Zagreb, Croatia.†Institute of Physics, Zagreb, Croatia.‡Division of Molecular Medicine, Ruder Boškovic Institute, Zagreb, Croatia.
Monomeric protein structure can form dimers, trimers and other aggregates induced by
different types of stressors. During protein association process different types of bonding may
occur, such as covalent, especially disulfide bonds, and non-covalent bonds: hydrogen bonds,
electrostatic interactions, Van der Waals interactions and hydrophobic bonds. Protein struc-
ture complexity makes mechanism of aggregates emergence entirely unrevealed or poorly
described.
Affected by these stressors, covalent and non-covalent bondage may occur and produce ir-
reversible or reversible protein aggregates. Irreversible aggregates can be produced through
heating, freezing-thawing, over-concentrating, isomerization, oxidation, etc. On the other
hand, reversible aggregates or self-associates might be formed by the aforementioned pro-
cesses but most likely by agitation1.
We examined the formation of dimers, trimers, and tetramers on rHuG-CSG, also known
as Granulocyte Colony Stimulating Factor, induced by agitation through a time period of 150
s. The analysis was performed immediately after agitation by liquid chromatography (gel
permeation) at pH= 7.0 (50 mM NH4HCO3 mobile phase). Due to increased pressure caused
by centripetal acceleration during agitation monomeric structures merges and makes dimers,
trimers, tetramers, and other aggregates. Increased agitation power results in a significant
increase of reversible self-associate quantity.
References
[1] R. Pavišic, I. Dodig, A. Horvatic, L. Mijic, M. Sedic, M. Rajic Linaric, I. Gruic Sovulj, T. Preocanin,
M. Bukvic Krajacic, M. Cindric, Differences between reversible (self-association) and irreversible
aggregation of rHuG-CSF in carbohydrate and polyol formulation. European Journal of Pharma-
ceutics and Biopharmaceutics 76 (2010) 357-365.
16
Horacio V. Guzman
Quantifying the disassembly of viral capsids from a multiscale molec-
ular simulation approach
Horacio V. Guzman?
?Jožef Stefan Institute, Ljubljana, Slovenia
Molecular simulation of large biological systems, such as viral capsids, remains a challeng-
ing task in soft matter research. On one hand, coarse-grained (CG) models attempt to make
feasible the description of the entire viral capsids. On the other hand, novel development of
molecular dynamics (MD) simulation approaches, like enhance sampling which attempt to
overcome the time scales required in biophysics. Those methods have a potential for deliv-
ering molecular structures and properties of biological systems. Nonetheless, exploring the
process on how a capsid disassembles by all-atom MD simulations has been rarely attempted.
Here, we propose a methodology to analyze the disassembly process of viral capsids quanti-
tatively. In particular, we look at the effect of pH and charge of the genetic material inside
the capsid, and compute the free energy of a disassembly trajectory by combining CG simu-
lations to a Poisson-Boltzmann solver. We employ such multiscale approach on the triatoma
virus as a test case, and find that even though an alkaline environment enhances the stability
of the capsid, the resulting deprotonation of the internal solvent generates an electrostatic
repulsion that triggers disassembly.
17
Clément Zankoc
Nonlinear stochastic dynamics of adherens junctions
Clément Zankoc?
?Department of Theoretical Physics, Jožef Stefan Institute, Ljubljana, Slovenia.
It is widely known that Myosin, a molecular motor, plays a fundamental role in epithelium
dynamics. Through its action, the sliding of anti-parallel actin filaments, coupled to the ad-
herens junction, it generates mechanical tension that leads to the shortening of the adherens
junction, and, therefore plays a key role in local topological rearrangment (T1-transition).
Indeed, it has been experimentally observed that periodic membrane contractions are ac-
companied by antiphasic myosin density oscillations. Inspired by these results and recent
literature, we propose an extension of the vertex model where the interplay between mem-
brane tension (i.e. myosin local density) and length is taken into account. We begin by
introducing a simple dynamical system which allows us to understand the main features of
such retroaction. We then extend our analysis on a larger scale system where such interplay
seems to be responsible for global rearrangements. Other important factors, such as tension
fluctuations, are also investigated.
18
Petra Papež
Hydration of lower alcohols using theoretical methods
Petra Papež?, Franci Merzel?
?Theory Department, National Institute of Chemistry, Ljubljana, Slovenia.
Hydrophobic hydration is a hydration of small and large hydrophobic solutes and it is
closely related to the hydrophobic effect. Hydrophobicity is an important driving force for
biomolecular processes, e.g., self-assembly of amphiphiles into micelles and membranes, pro-
tein folding, ligand binding. It is established that it manifests itself differently on micro and
macro length scales1–3 .
Figure 1: Structural ordering of water molecules around hydrophilic and hydrophobic parts
of lower alcohols.
The traditional explanation of hydrophobicity, is that the ”ice-like” structures (i.e., order-
ing of water molecules) are formed near the hydrophobic solutes, arising from strengthened
water hydrogen bonding4,5.
The experimental evidence supported by the results extracted from the ab initio molecular
dynamics simulations for the enhanced and more tetrahedrally oriented hydrogen bonds
near small purely hydrophobic solutes (methane, ethane, krypton, and xenon) was given
by Grdadolnik et al.6. There are structural changes in the arrangement of water molecules
around the hydrophilic and hydrophobic parts of the alcohol, however, they are not very
pronounced. In addition, structural changes are expected to be more pronounced in the
19
Petra Papež
presence of larger hydrophobic surfaces of alcohols (e.g., t-butanol). In this work we tried to
address the question regarding different structural ordering of water molecules around the
hydrophilic and hydrophobic parts of lower alcohols (methanol, ethanol, propan-1-ol, and
t-butanol) in very diluted solutions of alcohols and water (Figure 1). We found that water
around hydrophobic parts of alcohols shows greater structural order compared to the water
around hydrophilic parts.
References
[1] B. J. Berne, J. D. Weeks, R. Zhou: Dewetting and Hydrophobic Interaction in Physical and
Biological Systems. Annu. Rev. Phys. Chem. 2009, 60, 85–103.
[2] D. Chandler: Interfaces and the driving force of hydrophobic assembly. Nature 2005, 437, 640–
647.
[3] B. Kronberg: The hydrophobic effect. Curr. Opin. Colloid Interface Sci. 2016, 22, 14–22.
[4] H. S. Frank, M. W. Evans: Free Volume and Entropy in Condensed Systems III. Entropy in Binary
Liquid Mixtures; Partial Molal Entropy in Dilute Solutions; Structure and Thermodynamics in
Aqueous Electrolytes. J. Chem. Phys. 1945, 13, 507–532.
[5] W. Kauzmann: Some factors in the interpretation of protein denaturation. Adv. Protein Chem.
1959, 14, 1-63.
[6] J. Grdadolnik, F. Merzel, F. Avbelj: Origin of hydrophobicity and enhanced water hydrogen bond
strength near purely hydrophobic solutes. Proc. Natl. Acad. Sci. 2017, 114, 322–327.
20
Antonio Šiber
Collapsing pollen grains
Anže Božic?, Antonio Šiber†
?Department of Theoretical Physics, Jožef Stefan Institute, Ljubljana, Slovenia.†Institute of Physics, Zagreb, Croatia.
Pollen grains come in all sorts of shapes - they can be spherical, ellipsoidal, lobate, pris-
matic, polyhedral, and then, there are some which escape easy qualification in terms of
geometry. The sizes also differ very much, from less than 10 micrometers (e.g. in Myosotis
scorpioides or nontiscordardimè delle paludi, Vergissmeinnicht, mocvirska spomincica, and
mocvarni nezaboravak, as we say in Italian, German, Slovenian and Croatian, respectively)
to more than 100 micrometers (e.g. in Cucurbita pepo or zucchino, Gartenkürbis, buca, and
tikva). Shapes and sizes of grains depend on the specie in question and they are often used
to identify the plant, especially in the fossil records. Knowing that all life is related, it is
tempting to search for evolutionary reasons for different shapes and sizes of pollen grains. It
is also tempting to identify the elements of the "design" and relate them to the function which
the pollen grain needs to fulfil. Pollen grains are reasonably elastic shells which contain and
protect a sensitive interior - vegetative and generative cells, whose preservation is essential
for fertilization. They need to function on a border of stability, i.e. need to be sufficiently
strong to protect the interior, yet sufficiently labile to activate and release the interior once
they reach a suitable environment. This happens once they land on a stigma of a flowering
plant. In order to function properly, these shells need to conform to specific mechanical re-
quirements. These include the resistance of shells to the effective pressure from the outside -
the pollen grains crumple and deform upon desiccation. Yet, the crumpling (or buckling) is
often not irregular and catastrophic, which is what the word usually suggests in the mechan-
ical context. The inward buckling of the pollen grains proceeds often orderly and reversibly
due to specific mechanical features of the grain design. A classical theory of shell elasticity
can be profitably applied to learn more about such systems, as will be shown.
21
Angelo Rosa
Untangled ring polymers in melts: The Physics of crumpling
Angelo Rosa?
?Scuola Internazionale Superiore di Studi Avanzati, Trieste, Italy.
Unknotted and unconcatenated ring polymers in melt represent in many ways a puzzling
subject in Polymer Science, as they challenge the theoretical schemes commonly accepted
in the description of linear melts like screening of excluded volume effects and reptational
dynamics. In this talk, I will describe the state-of-the-art of this fascinating topic: in particular,
I will present recent results concerning an efficient numerical scheme to simulate large melts
of rings, discuss its limitations and highlight possible generalizations for future work.
22
Stefano Franzini
hicRED: A spectral method for comparing HiC-maps
Stefano Franzini?
?Scuola Internazionale Superiore di Studi Avanzati, Trieste, Italy.
HiC assays provide genome-wide maps of chromatin interactions, allowing researchers
to understand cell-type differentiation and disease emergence based on the 3D organization
of the genome. An open issue is assessing the reproducibility of repeated experiments and
finding significant differences between cell lines, a task made challenging by the presence
of multiple length-scales patterns and by the noisiness of the matrices. Spectral methods
exploit the innate hierarchy of the eigenspaces of HiC-maps to tackle the problem: here we
show, by comparison with the spectral properties of random matrices, that only a subset of
eigenspaces are robust, while the rest contain mainly noise. As a result we propose hicRED,
the HiC Reduced Eigenspace Distance, a novel method in which data are compared after a
single matrix spectral denoising procedure to classify experiments according to their cell lines
and identify meaningful differences between them.
23
Anže Božic
Coupling electrostatics and elasticity of virus capsids
Anže Božic?
?Department of Theoretical Physics, Jožef Stefan Institute, Ljubljana, Slovenia.
A major part of the interactions involved in the assembly and stability of small icosahedral
viruses is electrostatic in nature, as can be inferred from the strong pH- and salt-dependence
of their assembly phase diagrams. What is more, changes in environmental pH can induce
morphological changes in empty shells of viruses that cannot be explained with a simple
elastic model alone. I will present two models that combine the elasticity of thin icosahedral
shells and the pH dependence of their protein charges. The first model couples the elastic
parameters of the capsid to the electrostatic pressure acting on it. In this way, it is possible to
develop a clear theoretical description of radial swelling in virus-like particles that delineates
the importance of electrostatic contributions to swelling in the absence of any conformational
changes. The second model takes explicitly into account the positions and magnitudes of
protein charges and couples them with the thin-shell elastic model, predicting the equilibrium
shapes of viral shells that depend on a single elastic parameter and the configuration of
protein charges. I will show how the model can be applied to in vitro shell reconstructions of
bacteriophage HK97 in order to elucidate how some reversible transitions between different
procapsid states of HK97 are induced by pH changes.
24
Mattia Bernetti
Combining molecular dynamics simulations with SAXS experiments
to characterize RNA conformational dynamics
Mattia Bernetti?
?Scuola Internazionale Superiore di Studi Avanzati, Trieste, Italy.
RNA molecules are highly dynamic systems. In order to exert their biological functions,
they adopt a well-defined structural organization, which in turn allows establishing interac-
tions with specific molecular partners.1 Characterizing the mechanistic rearrangements lead-
ing to peculiar tertiary structures is thus of central interest to understand RNA roles. Despite
experimental techniques such as fluorescence spectroscopy and small-angle x-ray scattering
(SAXS) are well suited to obtain structural insights, their outcome data are generated as time
and ensemble averages and produce low resolution information. As such, interpreting them
unambiguously is not always straightforward. Therefore, integrating the available data with
an atomic-level outlook, as provided by molecular dynamics (MD) simulations, can be of
striking support.
We explore such possibility for the GTPase-associated center (GAC), a 58-nucleotide RNA
in the 23S ribosomal subunit, which must adopt a complex tertiary structure to associate with
its ribosomal protein partner L11 and play its function in protein translation. Recent SAXS
experiments reported on GAC structural flexibility in response to ions of different nature in
the buffer solution,2 noticing in particular that Mg2+ can stabilize the folded state, while
K+ favored less compact and more extended conformations. Using such experimental data
as a reference, we performed MD simulations and predicted SAXS spectra from the sampled
structures. Through this procedure, we thus aim at providing an atomic-level view of the
conformations adopted by GAC along its folding pathway.
References
[1] Al-Hashimi, H.M. and Walter, N.G. Curr. Opin. Struct. Biol., 2008, 18(3), 321-329.
[2] Welty, R., Pabit, S.A., Katz, A.M., Calvey, G.D., Pollack, L., Hall, K.B. RNA, 2018, 24(12), 1828-
38.
25
Nicola Calonaci
Machine-learning experimental data for RNA structure prediction
Nicola Calonaci?
?Scuola Internazionale Superiore di Studi Avanzati, Trieste, Italy.
Chemical probing and co-evolutionary data potentially encode structural information for
RNA molecules. We face the challenge of exploiting these data in the most efficient way
for RNA structure prediction. As we look for models that best reproduce available experi-
mental data without overfitting them, we consider machine-learning to be the most suitable
framework for the required balance between optimality and transferability. In this frame-
work we test two different approaches: discriminative and generative models. In both cases
we find our way to improve the accuracy of RNA secondary structure predictions, ensuring
transferability via a robust pipeline of model selection and validation procedures.
26
Ina Erceg
The kinetics of bovine serum albumine adsorption on calcium ohos-
phate and TiO2 nanoparticles or nanotubes nanocomposites
Ina Erceg?, Vida Strasser?, Atida Selmani?, Jasmina Kontrec†, Damir Kralj†, IvanaTartaro Bujak‡, Brankica Mihaljevic‡, Maja Dutour Sikiric?
?Laboratory for Surface Chemistry and Biocolloids, Ruder Boškovic Institute, Zagreb, Croatia.†Laboratory for Precipitation Processes, Ruder Boškovic Institute, Zagreb, Croatia.‡Radiation Chemistry and Dosimetry Laboratory, Ruder Boškovic Institute, Zagreb, Croatia.
One of the largest health issue in modern society is increased frequency of hard tissues
chronic diseases1. Often the only treatment of such diseases is implementation with the
aim to regenerate damaged or diseased tissue. Considering that the main inorganic com-
ponent of hard tissue is biological apatite2, form of calcium phosphate (CaP), composite
materials based on calcium phosphate and different inorganic nanomaterials attracts atten-
tions as possible new and innovative implant materials. Among different nanomaterials,
TiO2 nanomaterials stand out because they can improve mechanical properties of CaP. Al-
bumine is one of three soluble proteins which adsorbs on the surface of implant materials
right after its implantation and affect their behavior in vivo3. But, its role in formation of
calcium phosphates on titanium implants is still not clarified. Therefore, the aim of this
study is to investigate the adsorption of bovine serum albumin (BSA) on nanocomposites of
calcium phosphate (CaP) and TiO2 nanoparticles (CaP/TiNP) or nanotubes (CaP/TiNT). In
order to do that, the kinetics of BSA adsorption kinetics of BSA adsorption on TiO2 nanopar-
ticles (TiNP), titanate nanotubes (TiNT), calcium deficient hydoxiapatite (CaDHA) obtained
in control system, CaP/TiNP and CaP/TiNT was measured on in situ in UV/VIS scanning
spectrophotomer. Samples obtained after adsorption were filtered and given for further anal-
ysis which included Fourier-transform infrared apectroscopy (FTIR), powder x-ray diffraction
(XRD) and scanning electron microscopy (SEM). The results of kinetics measurements were
modeled using kinetics models of pseudo-first, pseudo-second rate and interparticle diffusion
model. From the results of various kinetic models, the adsorption kinetics were found to
follow pseudo-second-order rate kinetic model for CaP/TiNT nanocomposites, respectively
pseudo-second-order rate and interparticle diffusion model for CaP/TiNP nanocomposites.
Results obtained from FTIR, XRD and SEM analysis showed that albumin did not influence
the composition and solid phase morphology.
27
Ina Erceg
Acknowledgment
This work has been financially supported by the Croatian Science Foundation under project
IP-2018-01-1493.
References
[1] Moroni, A. Nandakumar, F. B. De Groot, C. A. van Blitterswijk and P. Habibovic, J. Tissue Eng.
Regen. Med. 9 (2015) 745–759.
[2] S.V. Dorozhkin, in: Calcium Orthophosphates: Applications in Nature, Biology, and Medicine,
Pan Stanford, Singapore, 2012.
[3] G. Khang, Evolution of gradient concept for the application of regenerative medicine, Biosurface
Biotribology. 1 (2015) 202–213.
28
Anja Sadžak
Protection of lipid membranes during oxidative stress using flavo-
noid embedded silica nanoparticles
Anja Sadžak?, Lucija Mandic?, Vida Strasser?, Goran Baranovic?, Darija DomazetJurašin?, Maja Dutour Sikiric?, and Suzana Šegota?
?Ruder Boškovic Institute, Zagreb, Croatia.
Mesoporous silica nanoparticles were synthesized and stabilized using polyethylene gly-
col. Characterization was carried out using various methods, including XRD, FE-SEM and
AFM. Specific surface was determined using BET analysis and electrokinetic measurements
were performed in order to elucidate properties of MSNs in liquid media. MSNs were loaded
with structurally different flavonoids. It was shown that it is possible to efficiently load and
release flavonoids with different physicochemical and structural properties.
Interaction with model membranes was investigated using AFM and the protective role
of flavonoid was monitored before and after induced lipid peroxidation. Lipid peroxidation
was induced by addition of hydrogen peroxide.
The nanomechanical properties of DOPC membranes after lipid peroxidation confirmed
membrane damage, which was attenuated when using flavonoid loaded nanoparticles. By
applying combination of experimental techniques, this work generated detailed knowledge
about the effects of flavonoid loaded MSNs on the elasticity of model membranes, especially
under oxidative stress conditions.
29
Adela Štimac
Measurement of the biomolecular interaction between plant lectin
and peptidoglycan functionalized self-assembled hybrid bilayers
by a quartz crystal microbalance
Adela Štimac?
?Centre for Research and Knowledge Transfer in Biotechology, University of Zagreb, Croatia.
Peptidoglycan is the major component of bacterial cell walls which is recognized by the
innate immune system through a series of pattern recognition receptors (PRR), which play a
key role in first-line defense of the body1. Lectins, naturally occurring carbohydrate-binding
proteins, are involved in numerous biological processes and some of them act as PRR and bind
significantly to PGN2. In this study we were primarily interested to test interaction of pep-
tidoglycan monomer (PGM)3, disaccharide pentapeptide isolated from B. divaricatum with
model plant lectins, wheat germ agglutinin (WGA), by quartz crystal microbalance (QCM)
method. In order to study interactions of PGM with lectins, lipophilic derivative, PGM-oleyl
was synthesized and was used for preparation of the self-assembled hybrid bilayer membrane
(HBM). It was demonstrated that PGM was effectively recognized by WGA and that strength
of interactions depend on amount of PGM-oleil used for HBM preparation. The association
konstant for the binding of WGA to PGM functionalized hybrid bilayers was determined.
The results showed that the established QCM method for measurement of molecular
recognition between lectin and peptidoglycan functionalized HBM could be successfully em-
ploy in analyses of lectin-carbohydrate interactions, such as specificity, affinity and kinetics.
References
[1] A. J. Wolf, D. M. Underhill, Nat. Rev. Immunol. 2018, 18, 243-254.
[2] T. K. Dam, C. F. Brewer, Glycobiology 2010, 20, 270-279.
[3] J. Tomašic, I. Hršak, In Surface Structures of Microorganisms and Their Interaction with the
Mammlian Host, E. Schrinner, M. H. Richmond, G. Seibert, U. Schwartz, Eds., VCH: Weinheim
1988, 113-121.
30
Matej Kanduc
Biological liquids under tension
Matej Kanduc?
?Department of Theoretical Physics, Jožef Stefan Institute, Ljubljana, Slovenia.
Numerous biological systems contain metastable liquids at considerable negative pres-
sures. As a prominent example, plants use negative pressures to suck water from the soil
into their leaves. A long-debated mystery is why the maximal negative pressures are ap-
proximately -100 bar. An ubiquitous ingredient of biological liquids are lipids. Combining
atomistic simulations and kinetic modeling, we show that lipid bilayers lead to cavitation at
negative pressures of about -100 bar over time scales of hours to days, whereas water with
added salt or nonpolar gas stay stable over many years. Our findings show that the presence
of lipid aggregates imposes an upper limit for the magnitude of negative pressure and with
that restricts the height up to which trees can grow.
31
Andraz Gnidovec
Orientational ordering of point dipoles on a sphere
Andraz Gnidovec?
?Faculty of Mathematics and Physics, University of Ljubljana, Ljubljana, Slovenia.
Distribution of interacting particles on a sphere is historically a well known problem,
however, ordering of systems on a sphere with anisotropic interaction, such as the dipole
dipole interaction, has remained unexplored. We solve orientational ordering of point dipoles
on a sphere with fixed positional order by numerically minimizing the system energy and
analyze stable configurations depending on their symmetry and degree of ordering. We find
macrovortex ground states with various rotational symmetries for different system sizes while
excited states also show other configurations. We explore system response in external field
both for the fixed sphere as well as for the freely-rotating sphere and study the orientational
phase transitions that emerge with increasing field amplitude. For the case of freely rotating
sphere, we also observe the change of configuration symmetry for certain states at higher
field amplitudes.
32
Matej Krajnc
Active elastic networks as models of biological tissues
Matej Krajnc?
?Department of Theoretical Physics, Jožef Stefan Institute, Ljubljana, Slovenia.
Epithelial monolayers usually appear close to 100% confluency and yet their constituent
cells are often able to exchange neighbors and travel across tissue-scale distances. This is
enabled by active processes at the cell-cortex level, which act as local energy sources to drive
cells over the energy barriers for rearrangement. Using a two-dimensional vertex model of
polygonal cells, we study the transition from a solid-like to a fluid-like behavior of tissues
with a stochastic turnover dynamics of molecular motors at cell-cell junctions. We show
that the diffusion coefficient of cell movements becomes finite at a critical value of tension
fluctuations. While this critical value depends on the persistence time of molecular motors,
the diffusion coefficient surprisingly collapses when plotted against the average cell-shape
index. This results suggests that the degree of cell movements can be measured from static
images of tissues with no need for cell tracking. To better understand the cell-rearrangement
dynamics under tension fluctuations, we also develop a simple Markov-chain model and
discuss a new machine-learning-based approach. Here, the algorithm, previously trained on
the vertex model, can efficiently mimic the vertex-model dynamics with no need of explicit
force calculations and solving the system of differential equations.
33
Primoz Ziherl
Morphologies of vesicle doublets: Competition among surface ten-
sion, bending elasticity, and adhesion
Kei Murakami?, Ryuta Ebihara?, Takuma Kono?, Toshikaze Chiba?, Yuka Sakuma?,
Primož Ziherl†‡, and Masayuki Imai?
?Department of Physics, Tohoku University, Aoba, Sendai, Japan.†Faculty of Mathematics and Physics, University of Ljubljana, Slovenia.‡Department of Theoretical Physics, Jožef Stefan Institute, Ljubljana, Slovenia.
We experimentally investigate the morphology of doublets of giant unilamellar vesicles
suspended in a salt solution which controls the strength of intermembrane adhesion. Using a
hot stage, we explore the transformation of doublets from the spherical-cap shapes to either
prolate doubles or to doublets with a spherical external shape and a sigmoidal contact zone
seen in the weak- and strong-adhesion regime, respectively. The observations are interpreted
using the standard theory of vesicle elasticity generalized so as to allow for two distinct sur-
face tensions, and the shapes obtained numerically using the Surface Evolver package agree
rather well with the experimental images. The best-fit adhesion strengths agree well with the
theoretical predictions including the van der Waals attraction as well as the undulation and
screened electrostatic repulsion.
34
Index of authors
Baranovic, 29
Bernetti, 25
Božic, 21, 24
Brkic, 16
Bujak, 27
Calonaci, 26
Chiba, 34
Cindric, 16
Corominas-Murtra, 10
Doncevic, 16
Ebihara, 34
Erceg, 27
Franzini, 23
Frkanec, L., 14
Frkanec, R., 14
Gnidovec, 32
Hribar-Lee, 13
Imai, 34
Jurašin, 29
Kanduc, 31
Kono, 34
Kontrec, 27
Krajnc, 33
Kralj, 27
Mandic, 29
Merzel, 19
Mihaljevic, 27
Murakami, 34
Papež, 19
Rosa, 22
Rozman, 11
Sadžak, 29
Sakuma, 34
Šegota, 29
Selmani, 27
Šiber, 21
Sikiric, 27, 29
Slejko, 13
Staniscia, 15
Štimac, 14, 30
Strasser, 27, 29
Svetina, 12
V. Guzman, 17
Vuletic, 14
Zankoc, 18
Ziherl, 34
35